JP2012191619A - Mobile phone - Google Patents

Abstract

PROBLEM TO BE SOLVED: To determine a health-related parameter by means of a mobile phone.SOLUTION: A mobile phone comprises: a casing; a cavity in the casing; a humidity sensor arranged to measure humidity in the cavity; a control unit to analyze a humidity signal supplied by the humidity sensor; an output unit to present a result of the analysis.

Description

CROSS REFERENCE TO RELATED APPLICATIONS This application claims the priority of European Patent Application No. 11001945.2 filed on March 9, 2011, the entire disclosure content of European Patent Application No. 11001945.2 is Included herein by reference.

TECHNICAL FIELD The present invention relates to a mobile phone, a method for operating a mobile phone and a corresponding computer program element.

  Mobile phones can now function as portable, multi-function electronic devices rather than just phones, thanks to miniaturization and improved wireless technology.

  An object of the present invention is to obtain health-related parameters using a mobile phone.

  This problem is solved by the mobile phone according to claim 1. This mobile phone has a casing, and the casing has a recess. A humidity sensor is arranged to measure the humidity in the recess. A control unit is also provided, which analyzes the humidity signal supplied from the humidity sensor. An output unit is provided to present the result of this analysis.

  The mobile phone according to the present invention can function as a device for measuring and analyzing the humidity of the user's skin. In that sense, the mobile phone can provide information on the user's skin condition, such as information on how to take beauty and / or health related treatments according to the displayed results.

  In addition, the concave portion and the humidity sensor are arranged on the mobile phone so that when the user's body part covers the passage to the concave portion, for example, a window, transepidermal water loss occurs from the user's skin into the concave portion. The Transepidermal water loss from the user's skin appears as evaporation of water into the recesses, increasing the humidity in the recesses. In this embodiment, the recess is a space filled with air and accepts transepidermal water loss as moisture to fill such limited air volume. The recess is preferably formed and arranged such that when the window is covered by the body part, the recess is sealed, resulting in a higher humidity in the air volume. The air in the recess cannot leak into the environment through the window covered by the body part, nor can it leak into the mobile phone through the wall of the recess. The wall of the recess is preferably leakproof.

  In an advantageous embodiment, the humidity sensor provides a humidity signal representative of relative humidity. Relative humidity is defined as absolute humidity divided by the maximum humidity that air can accept. The humidity signal is processed before being supplied to the control unit or analyzed in the control unit. Such processing may include, without limitation, one or more of filtering, amplification, compensation for unwanted effects, dynamic compensation, and formation of any derivative amount. Furthermore, irrespective of such processing, the signal supplied to the control unit or analyzed there is regarded as a humidity signal. In other embodiments, any such signal processing is considered part of the analysis when performed by the control unit.

  The humidity sensor is preferably a type of sensor that detects water molecules present around the humidity sensor. In a preferred embodiment, the humidity sensor includes a layer made of ceramic or polymer. Such materials allow water molecules to enter the layer. As a result, the capacitance of the layer changes, and the change is detected by the electrode used to determine the capacitance of the layer.

  In a preferred embodiment, rather than analyzing the pure humidity level from the corresponding humidity signal, the characteristics over time of the humidity signal, i.e. the dynamic characteristics, are used. In the analysis, such dynamic characteristics may be used alone or in combination with the humidity level. In a highly preferred embodiment, the control unit is adapted to determine the change of the humidity signal by determining the first or higher derivative of the humidity signal or by determining the change of the humidity signal within a predetermined period of time, for example. Composed. In particular, an increase or decrease in humidity signal is classified. For such purposes, an increase or decrease is compared to one or more thresholds. By appropriately selecting one or more threshold values, meaningful classification regarding the user's skin characteristics is realized. The start of measurement and / or analysis is triggered by the user pressing a key or touch key or by activating any other suitable input device. Preferably, the humidity level is measured and recorded in response to such a trigger event and used as a reference humidity value for one or more humidity values to be measured later.

  The window may be an opening assigned only to the humidity sensor, or may be an opening already present in the electronic device, such as a microphone opening of a mobile phone. In such cases, it is beneficial to make structural adaptive adjustments to form a recess below the microphone opening or elsewhere for the purpose of the subject.

  According to another aspect of the present invention, a method for operating a mobile phone is provided. In response to the trigger, the humidity signal supplied by the humidity sensor located in the recess of the mobile phone is analyzed. The result of this analysis is provided via the mobile phone output unit.

  According to yet another aspect of the invention, a computer program element according to the features of claim 15 is provided.

  Other advantageous embodiments are given in the dependent claims and in the following description.

  The described embodiments likewise belong to the above apparatus, method and computer program element. Although not described in detail, a synergistic effect may be generated from various combinations of the embodiments.

1 shows a schematic diagram of a mobile phone according to an embodiment of the present invention. FIG. FIG. 2 shows a cross-section along the line AA in FIG. 1 of a recess in the casing of the mobile phone in two usage scenarios a) and b). 6 shows a cross section of a recess in a casing of a mobile phone according to another embodiment of the present invention. 1 shows a schematic diagram of a mobile phone according to an embodiment of the present invention. FIG. FIG. 3 shows another schematic diagram of a mobile phone according to an embodiment of the present invention. Fig. 5 shows a sample of humidity signal characteristics measured by a mobile phone according to an embodiment of the present invention. 2 shows a flowchart of a method for operating a mobile phone according to an embodiment of the present invention.

FIG. 1 shows a schematic top view of a mobile phone according to an embodiment of the present invention. The mobile phone 1 includes a standard microphone 16, a standard speaker 32 and an output unit 14 in the form of a display 141. Further, the mobile phone 1 has a window 152 in the casing 15 of the mobile phone 1.

  FIG. 2 a) shows a cross section along the line AA in FIG. 1 of the recess 151 arranged in the casing 15 under the window 152. The concave portion 151 has a blind hole shape, and is formed by a wall without leakage of the casing 15. The window 152 connects the recess 151 to the external EX of the casing 15. A humidity sensor 12 is disposed at the bottom of the recess 151 in order to measure the humidity in the recess 151. The humidity sensor 12 may be disposed on a substrate that forms at least a part of the bottom of the recess 151.

  In the scenario shown in FIG. 2 a), the humidity in the recess 151 is approximately equal to the external EX of the mobile phone 1, that is, the humidity in the surrounding environment. Window 152 allows air exchange between the external EX and the recess 151.

  In FIG. 2b) the recess of FIG. 2a) is again shown in a different use scenario. It is assumed that the user covers the window 152 of the casing 15 with a part of skin such as the thumb THU. By doing so, the volume of the recess 151 is separated from the external EX of the mobile phone 1, and the humidity in the recess 151 is governed by the humidity resulting from transepidermal water loss through the skin of the user's thumb THU. In such a scenario, the recess 151 is hermetically closed to the outside by the thumb THU covering the window, and hermetically closed to the interior IN of the casing by the wall of the recess.

  Of course, the effect of separating the recess 151 from the external EX so that the humidity in the recess 151 is influenced by transepidermal water loss is that the user can use the mobile phone 1 in another part of the body, for example, for a call. It is also effective to cover the window 152 with the cheek when holding it. While the user covers the window 152 with a body part, the humidity in the recess 151 first increases in response to such transepidermal water loss and then saturates.

  The humidity signal RH (t) supplied by the humidity sensor 12 reflects such a change in the humidity in the recess 151. According to FIG. 4 which shows a schematic diagram of a mobile phone 1 according to an embodiment of the present invention, such a humidity signal RH (t) is supplied to the control unit 11 of the mobile phone 1 by the humidity sensor 12. Be analyzed. The control unit 11 is realized by a logic circuit, software or other means. The analysis is based on the humidity signal RH (t), in particular the characteristics of the humidity signal RH (t) over time, that is, the dynamic characteristics of the humidity signal RH (t) and the nature of the user's skin, in particular the skin humidity state. You may focus on pulling out. Such information is provided to the user via the output unit 14. In terms of reference signs, a signal C (t) representing such information to be output to the user is sent by the control unit 11 to the output unit 14.

Referring now to FIG. 6, a sample of relative humidity characteristics RH (t) over time is shown. Here, at t <t _x, it is assumed that the window 152 of the casing 51 is not covered so that the humidity sensor 12 basically detects the humidity of the external EX of the mobile phone 1. Also, at t = t _x , it is assumed that the mobile phone user triggers the skin moisture analysis function and at about the same time the window 152 is covered with a part of the user's skin, for example the thumb, thereby closing the recess 151. .

The trigger may be performed by the user pressing a key or touch key, or by other human machine interface. At the trigger time t _x , the current humidity value RH (t _x ) = RH _tx is measured and stored in the memory of the mobile phone 1 as the reference humidity value RH _tx . Preferably, such a reference humidity value RH _tx represents the humidity of the surrounding environment of the mobile phone, not the humidity caused by humans.

  In the first embodiment of the analysis, the subsequent dynamic characteristic of the humidity signal RH (t) is determined, for example, by determining the first derivative or any higher order derivative of the humidity signal RH (t), or of the humidity signal RH (t). Analyzed by determining the response time.

In another embodiment of the analysis, at which time t _{y the} humidity change ΔRH relative to the reference humidity value RH _tx reaches a predetermined target change TH _RH relative to the trigger time t _x , ie RH (t _y ) => It is checked whether RH _x + TH _RH . For example, if a new humidity signal value RH is supplied every Δst seconds, for example every 500 ms, and time t = t _x + mΔst (where m is an integer) for each such supply, RH (t _x + mΔst ) -RH _x => TH _RH is determined. (See graph in FIG. 6) this condition at some point in time t _y is satisfied, the time t _y obtained is classified to permit inferences about the humidity balance of the user's skin.

In yet another embodiment, the analysis may be such that a predetermined period Δt begins at the trigger time t _x . In this analysis, it is of interest what level of humidity has been reached after the elapse of a predetermined period Δt, ie at the time t = t _x + Δt. In the example of FIG. 6, the humidity value RH (t _x + Δt) = RH _{tx + Δt} is obtained at the end of such a period. By subtracting the reference humidity value RH _x from the humidity value RH _{tx + Δt} , the humidity change ΔRH = RH _{tx + Δt} −RH _x in the period Δt is obtained, and the user's skin is, for example, “dry skin”. Useful for assigning skin moisture class. Such results are provided to the user via the output unit 14, for example in the form of characters or symbols displayed on a display. In this regard, inferences regarding the humidity characteristics of the skin may be made possible by the dynamic characteristics of the humidity signal. For example, the greater the humidity change ΔRH = RH _{tx + Δt} −RH _tx in the predetermined period Δt, the greater the moisture that evaporates into the recess 151. As a result, a conclusion is reached that the humidity of the user's skin is sufficient. In addition to the humidity change ΔRH = RH _{tx + Δt} −RH _tx , the classification may be determined by the absolute humidity value RH _{tx + Δt} achieved at the end of the period t = t _x + Δt.

Preferably, when the end of the period Δt is reached, ie at t = t _x + Δt, an acoustic signal such as a beep is emitted to inform the user that the measurement is complete and that the window 152 no longer has to be covered. You may let me know.

The humidity signal RH (t) in FIG. 6 represents a usage scenario in which the casing window is covered with a part of the body and the trigger is simultaneous. A subsequent increase in relative humidity within the recess is detected. In different usage scenarios, the user covers the window with a part of the body before the trigger. At the time of the trigger, the body part may be moved away from the window. Thereafter, the air in the concave portion containing moisture derived from transepidermal water loss escapes to the outside, so that the relative humidity in the measured concave portion decreases. Such a decrease is detected and subsequently analyzed. Preferably, the corresponding humidity level is recorded at the trigger time t = t _{x and} the dynamic characteristics of the subsequent humidity signal are examined.

  The flowchart of FIG. 7 shows a method similar to the method described above. The method starts at the first step 30. The starting step includes, for example, switching on the mobile phone. In step 31, it is verified whether the user has triggered the humidity measurement process, for example by pressing a key on the mobile phone. If the user has not yet triggered such a process (N), it continuously waits for such a trigger signal. If the user triggers such a process (Y), then the user's skin humidity is measured and presented to the user. Instead of step 31, the process may wait for an interrupt as a trigger signal that initiates subsequent measurement and analysis steps.

  In step 32, the current humidity value is measured and stored as a reference humidity value. In step 33, the derivative of the humidity signal is determined. Optionally, in step 34, additional information may be extracted from the humidity signal RH (t) if necessary. In step 35, the derivative is compared to one or more thresholds for classifying the measurement result, for example by assigning a humidity class to the measurement result. In step 36, the result of such classification is provided to the mobile phone output unit. This step returns the process to step 31 in preparation for a new measurement and analysis.

  Depending on how the humidity signal is analyzed, step 35 may have different analysis contents, and step 33 may be otherwise prepared for analysis.

  Returning to FIG. 4, according to another embodiment, the mobile phone 1 includes a temperature sensor 13 that supplies a temperature signal T (t) to the control unit 11. The temperature sensor 13 is arranged so as to measure the temperature of the user's skin when the user covers the recess 151 with a part of the body. In such a scenario, the user touches the area of the casing 15 near the window 152 where the temperature sensor or heat transfer element is located. According to the cross-section of the recess 151 of FIG. 3, such a heat conducting element 131 is formed on the outer surface of the casing 15 that interacts with the user's skin when the user covers the window 152 for skin humidity measurement. It may include a pad-like platform near the positioned window 152. Such a pad may be connected to the temperature sensor 13 and the humidity sensor 12 arranged at the bottom of the recess 151 via a wire-like structure, for example. The temperature sensor 13 and the humidity sensor 12 are arranged on a common substrate (not shown). By touching the heat conducting element 131, body heat is transmitted to the temperature sensor 13 and converted into a temperature signal T (t) in the temperature sensor 13. According to FIG. 4, such a temperature signal T (t) is supplied to the control unit 11. The control unit 11 analyzes the temperature signal T (t) and / or simply displays the measured temperature, for example on the display 141 of the mobile phone. The process of measuring the temperature signal T (t) may be triggered by the user pressing a key or touch key, automatically triggered simultaneously with the humidity measurement, or triggered independently of it. Also good.

  Further, the recess 151 may be divided into two volumes 1511 and 1512 by a breathable membrane 153 shown in FIG. In this embodiment, the humidity sensor 12 is arranged to measure the humidity in the second volume 1512 limited by the recessed wall and the humidity sensor or its substrate and the membrane 153, while the first volume 1511 is a window. 152. The membrane 153 acts as a low-pass filter for humidity. This is advantageous for small recess volumes as it prevents quick changes in the humidity signal. Therefore, the effect produced by the membrane is desirable to make the measurement more accurate.

  FIG. 5 shows a hardware block diagram of the mobile phone 3 according to an embodiment of the present invention. In FIG. 5, the processing described in connection with FIGS. 4 and 6 is implemented as software resident in the memory 115 connected to the microprocessor 111 via the system bus 114, and is executed by the microprocessor 111 upon request. Executed. The humidity sensor 12 and the temperature sensor 13 are connected to the microprocessor 111 via the input system bus 112. Furthermore, a wireless interface 19 of the mobile phone 1 is also shown. The output unit 14 is connected to the microprocessor 111 via the output system bus 113. The control unit 11 may include elements within a dashed rectangle. In this embodiment, the control unit 11 is merged with the control unit of the entire mobile phone 1.

Claims (15)

In a mobile phone, the mobile phone
A casing (15) and a recess (151) of the casing (15);
A humidity sensor (12) arranged to measure humidity (RH) in the recess (151);
A control unit (11) for analyzing the humidity signal (RH (t)) supplied by the humidity sensor (12);
A mobile phone comprising an output unit (14) for presenting the result of the analysis.   The mobile phone has a window (152) in the casing (15) that connects the recess (151) to the outside (EX) of the casing (15), and the recess (151) is formed on the body of the user. The mobile phone of claim 1, wherein the mobile phone is arranged to receive moisture resulting from transepidermal water loss when a portion covers the window (152). The mobile phone has a breathable membrane (153) disposed in the recess (151) to divide the recess (151) into a first volume (1511) and a second volume (1512). And
The first volume (1511) is connected to the window (152), and the second volume (1512) is limited by the membrane (153) and the wall of the recess,
The mobile phone according to claim 1 or 2, wherein the humidity sensor (12) is arranged to measure humidity (RH) in the second volume (1512).   The mobile phone according to any one of claims 1 to 3, wherein the humidity sensor (12) includes a layered sensing element that accepts water molecules from the air in the recess (151).   The mobile phone has a temperature sensor (13) arranged to measure the temperature of the part of the user's body when a part of the user's body covers the window (152); In particular, it has a heat conducting element (131) disposed on a common support (18) together with the humidity sensor (12) so as to transfer heat from the surface of the casing (15) to the temperature sensor (13). The mobile phone according to any one of claims 1 to 4.   The mobile phone according to any one of claims 1 to 5, wherein the control unit (11) is configured to analyze a time-dependent (t) characteristic of the humidity signal (RH (t)). The control unit (11) is configured to differentiate the humidity signal (RH (t)), a change (ΔRH) in the predetermined period (Δt) of the humidity signal (RH (t)), and the humidity signal (RH (t)). 7. The mobile phone according to claim 6, wherein the mobile phone is configured to determine one of the time points (t _y ) at which a predetermined target change (ΔRH = TH _RH ) is reached.   The mobile phone according to any one of claims 1 to 7, comprising means for triggering an analysis of the humidity signal (RH (t)). In response to the analysis trigger, the control unit (11) stores the current humidity value as a reference humidity value (RH _x );
Determining a skin humidity class according to an analysis of the time-dependent characteristics of the humidity value signal (RH (t)),
9. A mobile phone according to claim 8, wherein the mobile phone is configured to initiate presentation of the skin humidity class via the output unit (14). The control unit (11) determines the skin humidity class according to the change (ΔRH) of the humidity signal (RH (t)) and the humidity value (RH _{tx + Δt} ) achieved at the end of the predetermined period (Δt). The mobile phone according to any one of claims 1 to 9, wherein the mobile phone is configured to determine.   The mobile phone according to any one of claims 1 to 10, wherein the output unit (14) includes a display (141), and the result is displayed on the display (141). In a method for operating a mobile phone, the method is responsive to a trigger to a humidity signal (RH) supplied by a humidity sensor (12) disposed in a recess (151) of a casing (15) of the mobile phone (1). Analyzing (t));
Presenting the result of the analysis via an output unit (14) of the mobile phone (1).   13. A method according to claim 12, wherein the rise of the humidity signal (RH (t)) is analyzed in response to the trigger.   13. The method according to claim 12, wherein a decrease in the humidity signal (RH (t)) is analyzed in response to the trigger.   Computer program element comprising computer program code means for executing the method according to any one of claims 12 to 14 when executed on a microprocessor (111).

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